Michael catalytic

Acrylonitrile, polymerization, 120 Activity of phase-transfer catalysts Sjj2 reactions, 170-175 weak-nucleophile Sj.Ar reactions, 175-182 Acyltetracarbonyl cobalt compound, cleavage in the carboxyalkylation of alkyl halides, 150 Addition reactions, Michael, catalytic asymmetric, 69,70f... 

Hydrogen cyanide adds to an olefinic double bond most readily when an adjacent activating group is present in the molecule, eg, carbonyl or cyano groups. In these cases, a Michael addition proceeds readily under basic catalysis, as with acrylonitrile (qv) to yield succinonitnle [110-61-2], C4H4N2, iu high yield (13). Formation of acrylonitrile by addition across the acetylenic bond can be accompHshed under catalytic conditions (see Acetylene-DERIVED chemicals). 

Catalytic Hydroprocessing of Petroleum and Distillates, edited by Michael C. Oballah and Stuart S. Shih... 

Certain starting materials may give rise to the non-selective formation of regioisomeric enolates, leading to a mixture of isomeric products. Furthermore a ,/3-unsaturated carbonyl compounds tend to polymerize. The classical Michael procedure (i.e. polar solvent, catalytic amount of base) thus has some disadvantages, some of which can be avoided by use of preformed enolates. The CH-acidic carbonyl compound is converted to the corresponding enolate by treatment with an equimolar amount of a strong base, and in a second step the a ,/3-unsaturated carbonyl compound is added—often at low temperature. A similar procedure is applied for variants of the aldol reaction. 

Thus, condensation of isoniazide with acetone at the basic nitrogen gives the corresponding Shiff base (8). Catalytic reduction affords the antidepressant, iproniazid (9). Addition of the same basic nitrogen to methyl acrylate by Michael condensation leads to the 3-amino ester (10). This is converted to the amide, nialamide (11), on heating with benzylamine. 

The heterogeneous catalytic systems have some advantages over homogeneous re Chemical transformations under heterogeneous conditions can occur v/ith better efficiencies, higher purity of products, and easier work-up Balliniandcoworkers have found that commercial amberlyst A-27 is the best choice for the Michael addition of nittoalkanes v/ith fi-subsdnited alkene acceptors fEq 4111 The reacdon is also carried out by potassium carbonate in the presence of Aliquat 336 under idttasonic irradiadon fEq 4 112 ... 

The hydrogenation in the presence of Pd/G is also effective for the d compounds to amines. The Michael addition of nitromethime to 2-alkenoic esters followed by catalytic hydrogenation using 10% Pd/G in acetic acid md hydrolysis is a convenient method for the preparation of 3-alkyl-4-aminobut moic acids, which are importimt y-amino acids for biological snidy fEq. 6.48. The reduction c m be carried out at room temperanire md atmospheric pressure. 

An interesting approach to zr n.v-2,3-disubstituted cyeloalkanones is offered by auxiliary controlled intramolecular Michael additions. The diastereoselectivity depends on the chiral alcohol used193> l94. When the borneol derivative 7 was used as substrate, a single diastereomer of 8 resulted when the reaction was performed at 25 "C under thermodynamic control with a catalytic amount of sodium hydride in benzene. 

The application of auxiliary control in the asymmetric Michael addition of chiral enolates derived from ketones is rare the only example known is the use of (27 ,37 )-2,3-butancdiol as an auxiliary. The ketal of (27 ,37 )-2,3-butanediol with 3-methyl-l,2-cyclohexanedione reacts with 3-buten-2-one using as base a catalytic amount of sodium ethoxide in ethanol195. 

Methods for the catalytic enantioselective Michael addition have been developed using three different approaches ... 

Chinchona alkaloids, such as quinine, are readily available quinuclidine chiral bases which have been used extensively in catalytic Michael additions239 243. Methy 1-2,3-dihydro-1-oxo-l/f-in-dene-2-carboxylate (1) is most frequently used as the Michael donor in these studies. Enantiose-lectivities as high as 76% are reached in the additions to 3-buten-2-one. Modest enantioselec-tivities (< 67%) were also obtained with ethyl 2-oxo-l-cyclohexanecarboxylate and methyl l,3-dihydto-3-oxo-l-isobcnzol urancarboxylate244 245. 

In the presence of a catalytic amount of triethylamine, a readily enolizable carbonyl compound like acetylacetone (25) can undergo a Michael-type addition onto the triple bond of 23 with C-C bond formation, and subsequent 1,2-addition of the hydroxy group with elimination of an alcohol (MeOH or EtOH) to eventually yield a pyranylidene complex 28 (mode E) [29]. The most versatile access to / -donor-substituted ethenylcarbene complexes 27 is by Michael-type additions of nucleophiles, including alcohols [30-32], primary... 

The catalytic conditions (aqueous concentrated sodium hydroxide and tetraalkylammonium catalyst) are very useful in generating dihalo-carbenes from the corresponding haloforms. Dichlorocarbene thus generated reacts with alkenes to give high yields of dichlorocyclopropane derivatives,16 even in cases where other methods have failed,17 and with some hydrocarbons to yield dicholromethyl derivatives.18 Similar conditions are suited for the formation and reactions of dibromocar-benc,19 bromofluoro- and chlorofluorocarbene,20 and chlorothiophenoxy carbene,21 as well as the Michael addition of trichloromethyl carbanion to unsaturated nitriles, esters, and sulfones.22... 

In principle, numerous reports have detailed the possibility to modify an enzyme to carry out a different type of reaction than that of its attributed function, and the possibility to modify the cofactor of the enzyme has been well explored [8,10]. Recently, the possibility to directly observe reactions, normally not catalyzed by an enzyme when choosing a modified substrate, has been reported under the concept of catalytic promiscuity [9], a phenomenon that is believed to be involved in the appearance of new enzyme functions during the course of evolution [23]. A recent example of catalytic promiscuity of possible interest for novel biotransformations concerns the discovery that mutation of the nucleophilic serine residue in the active site of Candida antarctica lipase B produces a mutant (SerlOSAla) capable of efficiently catalyzing the Michael addition of acetyl acetone to methyl vinyl ketone [24]. The oxyanion hole is believed to be complex and activate the carbonyl group of the electrophile, while the histidine nucleophile takes care of generating the acetyl acetonate anion by deprotonation of the carbon (Figure 3.5). 

In particular, a,P-unsaturated aldehydes seldom give 1,4 addition. The Michael reaction has traditionally been performed in protic solvents, with catalytic amounts of base, but more recently better yields with fewer side reactions have... 

Other nucleophiles add to conjugated systems to give Michael-type products. Aniline derivatives add to conjugated aldehydes in the presence of a catalytic amount of DBU (p. 488). Amines add to conjugated esters in the presence of InCla, La(OTf)3, or YTb(OTf)3 at 3kbar, for example, to give P-amino esters. This reaction can be initiated photochemically. An intramolecular addition of an amine unit to a conjugated ketone in the presence of a palladium catalyst, or... 

This model clearly shows that the catalytic machinery involves a dyad of histidine and aspartate together with the oxyanion hole. Hence, it does not involve serine, which is the key amino acid in the hydrolytic activity of lipases, and, together with aspartate and histidine, constitutes the active site catalytic triad. This has been confirmed by constructing a mutant in which serine was replaced with alanine (Serl05Ala), and finding that it catalyzes the Michael additions even more efficiently than the wild-type enzyme (an example of induced catalytic promiscuity ) [105]. 

Ferrocen-l,l -diylbismetallacycles are conceptually attractive for the development of bimetal-catalyzed processes for one particular reason the distance between the reactive centers in a coordinated electrophile and a coordinated nucleophile is self-adjustable for specific tasks, because the activation energy for Cp ligand rotation is very low. In 2008, Peters and Jautze reported the application of the bis-palladacycle complex 56a to the enantioselective conjugate addition of a-cyanoacetates to enones (Fig. 31) [74—76] based on the idea that a soft bimetallic complex capable of simultaneously activating both Michael donor and acceptor would not only lead to superior catalytic activity, but also to an enhanced level of stereocontrol due to a highly organized transition state [77]. An a-cyanoacetate should be activated by enolization promoted by coordination of the nitrile moiety to one Pd(II)-center, while the enone should be activated as an electrophile by coordination of the olefinic double bond to the carbophilic Lewis acid [78],... 

Jautze S, Peters R (2010) Catalytic asymmetric Michael additions of a-cyano acetates. Synthesis 365-388... 

Even an entirely different enzyme can be changed to the one that has enolase activity. One representative example is the changing of a lipase to an aldolase utilizing the basicity of the catalytic triad via a simple mutation. The resulting promiscuous lipase has been demonstrated to catalyze the aldol reaction and Michael addition as shown in Fig. 23. 

Hydroaminomethylahon of alkenes [path (c)j wiU not be considered [12]. This review deals exclusively with the hydroaminahon reaction [path (d)], i.e. the direct addition of the N-H bond of NH3 or amines across unsaturated carbon-carbon bonds. It is devoted to the state of the art for the catalytic hydroamination of alkenes and styrenes but also of alkynes, 1,3-dienes and allenes, with no mention of activated substrates (such as Michael acceptors) for which the hydroamination occurs without catalysts. Similarly, the reachon of the N-H bond of amine derivatives such as carboxamides, tosylamides, ureas, etc. will not be considered. 

By using LaNa3-tris(binaphthoxide) (LSB) 55, catalytic asymmetric Michael addition of thiols to cycloalkenones took place to provide the adduct 56 with high ees in good yields (Eq. 7.41) [48]. 

In the above reaction one molecular proportion of sodium ethoxide is employed this Is Michael s original method for conducting the reaction, which is reversible and particularly so under these conditions, and in certain circumstances may lead to apparently abnormal results. With smaller amounts of sodium alkoxide (1/5 mol or so the so-called catalytic method) or in the presence of secondary amines, the equilibrium is usually more on the side of the adduct, and good yields of adducts are frequently obtained. An example of the Michael addition of the latter type is to be found in the formation of ethyl propane-1 1 3 3-tetracarboxylate (II) from formaldehyde and ethyl malonate in the presence of diethylamlne. Ethyl methylene-malonate (I) is formed intermefll-ately by the simple Knoevenagel reaction and this is followed by the Michael addition. Acid hydrolysis of (II) gives glutaric acid (III). 

There is a possibiUty that (hydroxymethyl)phosphines might be catalyzing hydration of activated olefinic moieties in lignin. The Michael addition reaction shown in eq. (6a) is catalyzed by 5% THP in water at ambient conditions, with 70% conversion of the acrylonitrile no such reaction is seen with aciyhc acid or the methyl ester, but analogous hydromethoxylation of these compounds is seen in MeOH (42) (eq. (6b), R = H or Me). There is a report on similar catalytic use of tiialkylphosphines, which, like THP, are strong nucleophiles (43). 

The first set of experiments was conducted in methanol. The substrate concentration was varied from 15 to 50 mM at a 200 pM concentration of 1 for the determination of kinetic parameters for the transformation of 8 into 9. The catalytic rate constant was determined to be 0.04 min and the Michael constant was determined to be 40 mM at 30°C. The rate constant is comparable to those reported for other dinuclear Cu(ll) complexes with a comparable Cu -Cu distance of 3.5 A, but about one magnitude lower than those observed for complexes with a shorter intermetallic distances (12-14), e.g. 2.9 A (kcat = 0.21 min ) (12) or 3.075 A (kcat = 0.32 min (13). The rate constant Aion for the spontaneous (imcatalyzed) oxidation of 8 into 9 was determined to be 6 x 10" min and corresponds to the oxidation without catalyst under otherwise identical conditions. The rate acceleration (Arca/Aion) deduced from these values is 60,000-fold. 

The solvent and temperature effects for the Michael addition of amidoxime 7 to DMAD were probed because the reaction itself occurs without any other catalysts. As shown in Table 6.2, the reaction gave a high ratio of 8E in strongly aprotic polar solvents such as DMF and DMSO (entry 1 and 2). 8E was also found as the major product in MeCN (entry 3), dichloromethane (entry 4), and xylenes (entry 5). To our delight, the desired 8Z was obtained as the major component in methanol (entry 6). The stereoselectivity of 8Z versus 8E was better at low temperature (entry 7). A similar result was observed when the reaction was run in THF or dichlo-roethane in the presence of a catalytic amount of DABCO (entries 9 and 10). 

However, when 2,6-dimethylbenzoquinone with sodium ( >3,5-hexadienoate (generated in situ) was reacted in water in the presence of a catalytic amount of sodium hydroxide, pentacyclic adducts were formed via deprotonation of the Diels-Alder adduct followed by tandem Michael-addition reactions with another molecule of 2,6-dimethylbenzoquinone (Eq. 12.25).83 Similar results were obtained with sodium ( >4,6-heptadienoate. 

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